The Jewell Instruments JMA-165 MEMS accelerometers are a cost effective and viable alternative to traditional force balance designs. This mighty little sensor is CENELEC, AREMA certified, and RoHS compliant. With options for heated or non-heated, and available filtering, you can customize the perfect sensor for your application. FEATURES ±0.5
The Jewell Instruments JMA-165 MEMS accelerometers are a cost effective and viable alternative to traditional force balance designs. This mighty little sensor is CENELEC, AREMA certified, and RoHS compliant. With options for heated or non-heated, and available filtering, you can customize the perfect sensor for your application. FEATURES ±0.5
Jewell Instruments AMA Series Accelerometers are an excellent choice for cost to performance trade off. The AMA is based on silicon micro-machined MEMS Capacitive Accelerometer technology and designed for low power and high stability. Analog output. FEATURES Single, Dual and Triaxial Configuration Excellent long term stability Ruggedized for harsh
Jewell Instruments DMA Series Accelerometers are an excellent choice for cost to performance trade off. The DMA is based on silicon micro-machined MEMS Capacitive Accelerometer technology and designed for low power and high stability. RS232 / RS485 TTL UART FEATURES Single, Dual and Triaxial Configuration Digital Communications Excellent long
The Model 7101A is a miniature, high performance IEPE accelerometer available in ±50g to ±1000g dynamic ranges. The accelerometer is designed for high frequency vibration and shock measurements and offers a wide bandwidth to >10kHz utilizing stable piezo-ceramic crystals in annular shear mode. The model 7101A features a hermetically sealed
High Performance Color Graphic LCD Screen TEDS Plug and Play Sampling and Response Time from 4,000 to 20,000 per second TEDS Read and Write Nonlinearity 0.01% Full Scale 24 Bit A/D Converter Remote Sense Function Variety of Hold Functions Scalable Analog Output (0-5 VDC, ±5 VDC, 0-10 VDC, ±10VDC, 4-20mA
The JDI-100/200 series is a digitally temperature compensated inclinometer available in single and dual axis configurations. The robust and rugged design is great for industrial use, yet includes the low-cost MEMS technology. These units are available with DB9, Pigtail, Deutsch, Double Deutsch, 6-Pin Circular (C06), or M12 connectors for maximum
T40MS Torque Transducer: from 500 Nm to 2 kNm at 25,000 rpm T40MS is outstanding for its precision, reproducibility and robustness and is particularly well-suited for static and dynamic torque measurement. The torque transducer features 0.03% accuracy in terms of linearity including hysteresis, as well as high temperature stability. Combined
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The AR100 is one of the smallest laser displacement sensors in the world. The ultra-compact AR100 comes with ranges from 10mm (0.4 in.) to 500mm (19.7 in.) with a single case size. It can take 9,400 measurements per second and has a linearity of ± 0.05% of the full measurement
The SomatXR MX471-R CAN bus module allows the simultaneous integration of up to four CAN networks into the SomatXR data acquisition system. This module is the more rugged version of the QuantumX MX471 and is ideal for use in extremely tough conditions, such as vehicle tests in the field and
CAN bus Module for Easy Integration of up to 4 CAN Networks The QuantumX MX471 CAN bus module allows the simultaneous integration of up to four CAN networks into the QuantumX data acquisition system and can be expanded as required. The module, combined with analog measurement modules, is ideally suited
TFX-5000 ultrasonic clamp-on meters are quickly and easily installed without cutting or tapping the pipe. Ultrasonic waves transmit upstream and downstream through the pipe wall and water flowing in the pipes. By measuring the difference in the travel time and knowing the pipe size, the meter determines the velocity and flow
Compatible with the entire range of Brüel & Kjær modal exciters, this unit serves two different purposes depending on which exciter is connected. When paired with Type 4827 or 4828, the unit provides variable stiffness to the armature suspension and correctly centres the armature in relation to both the exciter’s
The most powerful of our modal exciters, Types 4827 and 4828 offer precise and reliable operation in any modal testing scenario, including long-duration tests of outsized mechanical structures as well as applications with MISO and MISO configurations. Suitable for impulse, sine and random signals, they also have a wide frequency
As light and compact as Type 4824, these modal exciters are much more powerful. They combine a wide frequency range (DC – 5000 Hz) and up to 25.4 mm (1 in) of displacement for improved performance at low frequencies. Suitable for impulse, sine and random signals, Types 4825 and 4826
Powerful despite its small dimensions, Type 4824 is built to offer versatility and reliability in challenging modal applications, including SISO and SIMO tests of mechanical components, such as engines, as well as MISO and MISO tests of large structures. Suitable for impulse, sine and random signals, it also features a
The LDS® COMETUSB™ controller has been designed to offer an affordable and flexible solution for basic vibration testing needs. It is used in R&D and production test applications, such as stress screening. Its test profiles include random, sine, and shock excitations. It combines 24-bit precision with a wide dynamic control range and
Designed to generate a shaker drive signal and perform data measurements, the LDS® LASERUSB™ controller is typically used in R&D and production test applications, such as simulation of vibration and fatigue tests for automobiles, military vehicles, and ground transportation. It combines 24-bit precision with a wide dynamic control range and fast loop
SRS synthesis is used to evaluate the shock resistance of the DUT (device under test). This is achieved by synthesizing, within a closed-looped test system, a user-specified SRS profile of acceleration versus frequency in order to create complex transient waveforms for driving an electrodynamic shaker. The desired SRS profile is
Random-on-random (RoR) control simulates real-world complex vibration environments with a combination of a broadband random signal and one or more superimposed random narrow-bands. Both signal types are usually present simultaneously and the narrow-bands can appear at fixed frequencies or sweep over a predefined range. The overall random PSD (power spectral